Method and system for managing radio resources in a time-slotted communication system

ABSTRACT

A method and system for managing radio resources in a time-slotted wireless communication system is based on the quality of service (QoS) information of a user. A plurality of time slots of a radio resource are sorted into a plurality of different categories, such as high QoS time slots, high capacity time slots, and balanced time slots. Each category is associated with a different level of QoS. QoS information with respect to a user is obtained in response to a radio resource request received from the user. The user is associated with a particular category of time slots based on the QoS information of the user.

CROSS REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. Patent Application Ser. No. 10/886,735 filed on Jul. 8, 2004, which claims the benefit of U.S. Provisional Application No. 60/485.763 filed on Jul. 9, 2003, which are incorporated by reference as if fully set forth.

FIELD OF INVENTION

The present invention is related to a wireless communication system. More particularly, the present invention is related to a method and system for managing radio resources in a time-slotted wireless communication system based on quality of service (QoS) information of a user.

BACKGROUND

In conventional wireless communication systems, the demand for radio resources often exceeds their availability. Many schemes have been developed to share available radio resources among a plurality of users. The efficiency of the radio resource management (RRM) algorithms enhances the capacity of such systems.

Various Time Division Duplex (TDD) communication schemes exist today. The benefits of TDD systems include efficient and flexible use of bandwidth. For example, a channel can be configured to be either an uplink or downlink channel at any given time, based on traffic demands. However, resource management in a TDD system is challenging. As traffic patterns change rapidly over time, it is difficult to make optimal resource management decisions. Some of the resource management issues in a TDD system include the amount of bandwidth to assign a user, and the number of time slots to configure for uplink and downlink communications. Although various QoS schemes are currently known, most schemes depend on assigning a static QoS class to a given user and then forcing the system to act accordingly.

A method and system for more efficiently managing radio resources in a time-slotted communication system are desired.

SUMMARY

The present invention relates to radio resource management in a time-slotted system, such as a TDD or Time Division Multiple Access (TDMA) system. The system of the present invention designates a particular level of QoS and capacity to each time slot. In a preferred embodiment of the present invention, time slots (and users, geographic regions, and applications) are designated into three categories. In a first category designation, system capacity is a secondary concern, whereas QoS is considered as the most important issue. In a second category designation, system capacity is considered as more important than QoS. In a third category designation, the QoS and system capacity are both considered to be relatively equal in terms of importance.

A Radio Resource Management (RRM) function assigns the appropriate designation to a number of time slots based on statistical information of traffic patterns. The RRM function can use the admission control, congestion control, handover, user link maintenance and real time (RT) or non-real time (NRT) packet switching algorithm as a basis for allocating time slots for a particular user.

In one embodiment, a system receives a request for radio resources from a user. In response to the request, the system allocates a particular time slot to the user according to the user's QoS information obtained from a core network.

QoS criterion includes a status of user subscription, nature of user application, information regarding geographic region where the user requests radio resource, or the like. The system controls initial allocation of radio resources to a particular user based on the category designation associated with the user.

After initial allocation is established, the system constantly monitors the traffic conditions. If the system detects traffic congestion at time slots having a higher level of QoS, the system may increase the number of time slots having the higher level of QoS, and decrease the number of time slots having the lower level of QoS.

BRIEF DESCRIPTION OF THE DRAWING

A more detailed understanding of the invention may be had from the following description, given by way of example and to be understood in conjunction with the accompanying drawings wherein:

FIG. 1 is a block diagram of a time-slotted communication system in accordance with the present invention;

FIG. 2 is a flow diagram of a process including method steps for managing radio resources and monitoring various conditions in accordance with the present invention; and

FIG. 3 is a flow diagram of a process including method steps of sorting time slot categories and associating a user with a particular time slot category in accordance with the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The present invention will be described with reference to the drawing figures wherein like numerals represent like elements throughout. Hereafter, a base station includes but is not limited to a Node-B, site controller, access point or any other type of interfacing device in a wireless environment.

FIG. 1 is a block diagram of a wireless communication system 100, wherein a plurality of WTRUs 105 communicate with base stations 110. The base stations 110 are controlled by a radio network controller (RNC) 115. The RNC 115 is connected to a core network 120. Either the RNC 115 or the base stations 110 include a means for sorting a plurality of time slots of a radio resources into a plurality of different categories, and a means for mapping a user to a particular designation of time slots based on QoS information of the user which is obtained from a core network 120, as described in more detail below.

In a time-slotted communication system, a communication is transmitted over time slots. One or more time slots are designated to a particular user for either uplink or downlink communication. The system 100 of the present invention assigns one of a plurality of designations to time slots based upon the QoS of a user. In a preferred embodiment, the system 100 uses three designations: high QoS time slots, high capacity time slots, and balanced time slots. It should be understood that any number of designations may be used, and the title of the designations is simply for illustration of the preferred embodiment of the present invention. Accordingly, although three designations will be described hereinafter, more or less designations may be used. The priority scheme of the present invention may be used for either an uplink or a downlink channel.

Communication parameters, such as maximum delay, signal-to-interference ratio, packet error rate, and bit error rate, are defined differently for each designation of time slots. Therefore, a different level of QoS is provided to a time slot having a different designation.

High QoS time slots provide the highest QoS. As such, system capacity is a secondary concern for RRM, and is considered after QoS.

High capacity time slots provide only a minimum QoS. System capacity is a primary concern for RRM, and considered prior to QoS for high capacity time slots.

The QoS of balanced time slots falls between the high QoS time slots and the high capacity time slots. For RRM, system capacity and QoS are considered to be of relatively equal importance for balanced time slots.

RRM adjusts dynamically the parameters for each designation of time slot based on the traffic state. For example, in case of traffic congestion or lack of radio resources, communication parameters for balanced time slots are first adjusted to provide a minimum QoS. If congestion persists, calls from high capacity time-slots are dropped. Therefore, high QoS time slots are typically not adversely affected by traffic congestion.

The system may also designate time slots as RT slots or NRT slots. RT slots are more suitable for voice application, while NRT slots are more suitable for packet data applications. RT slots and NRT slots are differently controlled in terms of RRM. Communication parameters are defined differently for RT and NRT time slots. Therefore, different levels of QoS are provided to RT and NRT slots.

The system initially maps a user to a particular time slot designation based on QoS criterion and, thereafter, controls radio resources based on the same criterion. The QoS classification of the user depends on the overall QoS policy applied to the network. The QoS classification may include the status of the user's subscription, geographic information, the nature of the user's application, a QoS request, or the like. For example, in a commercial network, a user with a high level subscription is assigned to a high QoS time slot, irrespective of the QoS requirement of his communication, whereas a user with a low level subscription requesting a high QoS service is assigned to a balanced time slot.

In a preferred embodiment of the present invention, users are classified into three classes: a high QoS service subscriber, a high capacity service subscriber, and a balanced service subscriber. It should be understood that this classification is merely for illustration of the preferred embodiment of the present invention, and any number or title may be used. With some exceptions, high QoS time slots are assigned to high QoS service subscribers, balanced time slots are assigned to balanced service subscribers, and high capacity time slots are assigned to high capacity service subscribers. The system 100 controls the initial allocation of radio resources to a particular user based on the status of the subscription of the user.

The system 100 may also use operation and maintenance (OAM) information to make a decision of initial time slot assignment. For example, the operator could specify that certain radio access bearers should be sent to certain slots, such as all voice calls and high rate data calls (e.g. >384 kbps) should be sent to high QoS time slots, all medium rate data calls (e.g. 124 kbps-384 kbps) should be sent to balanced time slots, and all low rate data calls (e.g. <124 kbps) should be sent to high capacity time slots.

The system 100 may associate a particular geographic region to one of a plurality of time slot designations. For example, the system 100 may associate an airport or a train station to high QoS time slots. Only high QoS time slots are available for communication to and from these regions. Therefore, only a high QoS service subscriber can access radio resources in these regions. If a balanced service subscriber or a high capacity service subscriber desires to make a call in a region designated as a high. QoS zone, they must obtain a special grant to promote them to a high QoS service subscriber temporarily before making a call.

The system 100 may designate time slots based on the applications that the user uses. For example, a 911 call can be seen as a high QoS application. Therefore, any user who requests a 911 service may access a radio resource as a high QoS service subscriber, even though the user is not a high QoS service subscriber,

Different RRM algorithms are applied to different time slots. The RRM function assigns the appropriate number of time slots to each designation of time slots based on statistical information of traffic patterns. The RRM function can use the admission control, congestion control, handover, user link maintenance and RT or NRT packet switching algorithm.

FIG. 2 is a flow diagram of a process 200 including method steps for managing radio resources and monitoring various traffic conditions in accordance with the present invention. In step 205, the system 100 of FIG. 1 receives a radio resource request from a user of a WTRU 105. The radio resource request accompanies QoS information related to the request, the status of user subscription, the place of origination of the request, and the application that the user is using. In step 210, the core network 120 generates QoS information related to the user. In step 215, the QoS information is obtained from the core network 120. In step 220, the system 100 maps the user to an appropriately designated time slot (e.g., a high QoS time slot, a balanced time slot, a high capacity time slot, or the like) based on the QoS information of the user. As previously described, with some exceptions, high QoS time slots are assigned to high QoS service subscribers, balanced time slots are assigned to balanced service subscribers, and high capacity time slots are assigned to high capacity service subscribers. The system 100 controls the initial allocation of radio resources to a particular user based on the status of the subscription of the user.

After initial allocation is completed, the system 100 constantly monitors traffic status and, thereafter, controls radio resources according to a priority scheme in accordance with the present invention. Once the system 100 detects the occurrence of congestion, i.e., lack of radio resources (step 225), the system 100 dynamically adjusts the number of time slots assigned to each time slot designation (step 230). For example, if congestion occurs with high QoS time slots, the system 100 increases the number of high QoS time slots available and decreases the number of high capacity time slots available and, if necessary, the number of balanced time slots available after exhaustion of the available high capacity time slots. This may require the termination of calls or preventing a new access to high capacity time slots. Dropping calls or packets is considered to be a last resort. If congestion occurs with balanced time slots, the system 100 increases the number of balanced time slots available, and decreases the number of high capacity time slots available. However, the number of high QoS time slots is not adversely affected in this situation.

The system 100 may control handover according to the priority scheme of the present invention (step 235). Mobile units are permitted to rove among a plurality of cells. When a mobile unit crosses the boundary between two cells, a handover process is initiated. If there are not enough resources in the target cell, handover is not accomplished and a call might be dropped. In such situation, the system 100 frees high capacity time slots to be able to accept incoming high QoS users, and balanced requests are accepted by adjusting the QoS requirements in order to not congest the system 100, whereas high capacity requests would be rejected (step 240).

The system 100 may set the priority for NRT packet scheduling according to the priority scheme of the present invention (step 245). For example, users assigned to high QoS time slots are provided with the lowest delay and jitter for scheduling of data packets, users assigned to balanced time slots are provided with medium delay and jitter for data packet delivery, and users assigned to high capacity time slots are provided with the largest delay and jitter for transmission of data packets (step 250).

The system 100 may maintain link status with different data rates for each time slot designation (step 255). For example, high QoS time slots are given a guaranteed hit rate plus a predefined margin, and balanced time slots are given a guaranteed bit rate, and high capacity time slots are not guaranteed for a bit rate, but the actual connection may drop below the provided rate (step 260). If the system 100 detects a decrease in the data rate for a particular time slot designation, the system 100 may change the number of time slots of the designation according to the priority scheme of the present invention.

FIG. 3 is a flow diagram of a process 300 including method steps of sorting time slot categories and associating a user with a particular time slot category in accordance with the present invention. Radio resources are managed in a time-slotted wireless communication system 100 by sorting a plurality of time slots of the radio resource into a plurality of different categories, each category being associated with a different level of quality of service (QoS) (step 305). QoS information with respect to a user is obtained in response to a radio resource request received from the user (step 310). The user is then associated with a particular category of time slots based on the QoS information of the user (step 315).

While this invention has been particularly shown and described with reference to preferred embodiments, it will be understood by those skilled in the art that various changes in forms and details may be made therein without departing from the scope of the invention as described above. 

What is claimed is:
 1. A method of managing radio resources in a time-slotted wireless communication system, the method comprising: (a) sorting a plurality of time slots of a radio resource into a plurality of different categories, each category being associated with a different level of quality of service (QoS), each time slot being assigned one of a plurality of designations based upon the QoS of a user, wherein at least one communication parameter is defined differently for each time slot designation, and the at least one communication parameter is dynamically adjusted by a radio resource management (RRM) function based on a state of traffic; (b) constantly monitoring the state of the traffic; (c) if traffic congestion occurs or the data rate for a particular time slot designation changes, dynamically adjusting the number of time slots assigned to each time slot designation; (d) if a handover is initiated and there are not enough resources in a desired target cell to which the handover is directed, freeing high capacity time slots and adjusting QoS requirements to avoid traffic congestion; and (e) if data packet scheduling is required, adjusting delay and jitter for scheduling the data packets based on time slot designation.
 2. The method of claim 1 wherein the time slot designations include at least one of a high QoS time slot, a high capacity time slot, a balanced time slot, a real time (RT) time slot and a non-real time (NRT) time slot.
 3. The method of claim 1 wherein the at least one communication parameter includes at least one of maximum delay, signal-to-interference ratio, packet error rate and bit error rate.
 4. A time-slotted wireless system for managing radio resources, the system comprising: (a) means for sorting a plurality of time slots of a radio resource into a plurality of different categories, each category being associated with a different level of quality of service (QoS), each time slot being assigned one of a plurality of designations based upon the QoS of a user, wherein at least one communication parameter is defined differently for each time slot designation, and the at least one communication parameter is dynamically adjusted by a radio resource management (RRM) function based on a state of traffic; (b) means for constantly monitoring the state of the traffic; (c) means for dynamically adjusting the number of time slots assigned to each time slot designation if traffic congestion occurs or the data rate for a particular time slot designation changes; (d) means for freeing high capacity time slots and adjusting QoS requirements to avoid traffic congestion if a handover is initiated and there are not enough resources in a desired target cell to which the handover is directed; and (e) means for adjusting delay and jitter for scheduling the data packets based on time slot designation if data packet scheduling is required.
 5. The system of claim 4 wherein the time slot designations include at least one of a high QoS time slot, a high capacity time slot, a balanced time slot, a real time (RT) time slot and a non-real time (NRT) time slot.
 6. The system of claim 4 wherein the at least one communication parameter includes at least one of maximum delay, signal-to-interference ratio, packet error rate and bit error rate.
 7. A radio network controller (RNC) for managing radio resources in a time-slotted wireless communication system, the RNC comprising: (a) means for sorting a plurality of time slots of a radio resource into a plurality of different categories, each category being associated with a different level of quality of service (QoS), each time slot being assigned one of a plurality of designations based upon the QoS of a user, wherein at least one communication parameter is defined differently for each time slot designation, and the at least one communication parameter is dynamically adjusted by a radio resource management (RRM) function based on a state of traffic; (b) means for constantly monitoring the state of the traffic; (c) means for dynamically adjusting the number of time slots assigned to each time slot designation if traffic congestion occurs or the data rate for a particular time slot designation changes; (d) means for freeing high capacity time slots and adjusting QoS requirements to avoid traffic congestion if a handover is initiated and there are not enough resources in a desired target cell to which the handover is directed; and (e) means for adjusting delay and jitter for scheduling the data packets based on time slot designation if data packet scheduling is required.
 8. The RNC of claim 7 wherein the time slot designations include at least one of a high QoS time slot, a high capacity time slot, a balanced time slot, a real time (RT) time slot and a non-real time (NRT) time slot.
 9. The RNC of claim 7 wherein the at least one communication parameter includes at least one of maximum delay, signal-to-interference ratio, packet error rate and bit error rate. 